DE2843977A1 - TV sound signal recovery for HF carrier mode - mixes IF picture signal, which is then filtered out, to obtain IF sound signals near picture carrier - Google Patents

Abstract

The circuit is designed to recover the sound signal from a HF carrier or a transmitted TV signal. After a first mixing the IF picture signal band is filtered out, and a signal containing the IF sound signals and signals near the IF picture carrier is collected. Sound signals in the difference frequency position are obtained by a second mixing. Composite signal necessary for the second mixer is collected from the picture IF filter by an i.f. sound carrier trap behind an attenuation peak each for an adjacent carrier of the upper and lower adjacent channel. It contains also the IF picture carrier and adjacent modulation frequencies of sufficient amplitude. In the combined signal oscillation pattern, the amplitudes of the sound-carrier IF oscillation and those of the picture. IF signals are approximately in the ratio of 1:3 to 3:1 pref. 1:1. The combined signal oscillations are decoupled in a sound-carrier-cascade stage in which the picture IF signal oscillations are at a max. in the region of the picture carrier-signal.

Description

"Circuit arrangement for obtaining the audio signals from a

Television signal "The invention relates to a circuit arrangement for extracting the audio signals from one transmitted on a high frequency carrier TV signal in which, after a first mixture, to gain the IF oscillations On the one hand, the intermediate-frequency image signal band is separated in a filter and on the other hand a signal range which is made up of the intermediate-frequency sound signals and synthesizes signals in the vicinity of the intermediate frequency picture carrier and from this, through a second mixture, the audio signals in the difference frequency position be won.

Such a circuit arrangement is known as a quasi-parallel tone from the FUNKSCHAU issue 9/1978.

The object of the invention is to suppress video modulation and other interferences as well as the signal-to-noise behavior in the audio channel and at the same time, especially when using integrated circuits, the effort is low to keep.

To solve this problem are according to the invention for the second Mixing required composite signal oscillations from the image IF filter decoupled by means of an IF sound carrier trap behind at least one Damping pole arranged for an adjacent carrier of the upper and the lower adjacent channel is and in which also vibrations of the image carrier IF and, if necessary, at least one Part, oscillations of the neighboring modulation frequencies transmitted as a double sideband signal occur with an amplitude sufficient for mixing.

The decoupling is expediently carried out in a sound carrier trap in which the image carrier IF oscillations have a maximum approximately in the vicinity of the image carrier.

Due to the coupling made according to the invention act the traps or traps in the preceding filter section

Blocking circuits, e.g. for the adjacent-channel video carrier and the adjacent-channel sound carrier, as edge limitation for the decoupled composite signal range, so that interference from the adjacent channels is suppressed to a particular degree, without increasing the cost of selection means.

The sound carrier trap used for decoupling can be replaced by another Resonance between image carrier and sound carrier as a damping pole for a subharmonic the differential carrier frequency of, for example, 5.5 MHz; the attenuation pole is then placed on an intermediate frequency that is a distance from the image carrier of about 2.75 and 1.83 MHz, respectively.

The decoupled vibrations can after a development of the Invention of a filter matched to the picture carrier IF and a limiter amplifier the second mixer stage as reference vibrations, expediently with a phase shift of about 90 ° compared to the image carrier IF oscillations added at the signal input will. This gives a single sideband demodulation in which the undesired and by limiting already reduced two sideband components are additionally suppressed in the vicinity of the image carrier.

The invention is illustrated below with reference to the drawing, for example explained in more detail, which in Fig. 1 shows an example with a filter to which the composite Vibrations are taken, and integrated with one shown in function blocks Circuit for obtaining the tone difference frequency signal.

Fig. 2 shows an embodiment of a circuit arrangement for Low-distortion amplification and limiting of the composite signal (for obtaining of the reference signal).

The filter according to FIG. 1 is received from a signal source 1 Vibrations of a television station are supplied in the intermediate frequency position, which is shown in a tuning unit, not shown, with the aid of an oscillator and a first Mixing stage were obtained. An impedance is effective at the output of this signal source 1, which consists of an effective resistance 2, an inductance 3 and a capacitance 4, which are indicated in the drawing for the sake of completeness, since they are connected to the input terminal 5 occur and are taken into account when calculating the following filter Need to become.

For the invention, the structure and design of the entire up to the output terminal 6 interconnected filters are not particularly important.

In the vibrations supplied to such a filter, the image carrier a frequency of 38.9 MHz and the sound carrier offset by 5.5 MHz one frequency of 33.4 MHz; the neighboring sound carrier is then at 40.4 MHz for one reception in the VHF range or at 41.4 MHz when receiving in the UHF range, and the neighboring video carrier is 31.9 MHz. the Attenuation poles for these frequencies can realized in the filter areas 11, 12 and 14 indicated with clarifiers in FIG 3 a.

In area 13 there is a trap for your own sound carrier, which is formed by the series connection of a capacitor 1e and 27 pF a capacitor 17 of 26 pF with parallel inductance 18, which is from the TeilinduktisTitaten 13a and 18b in series with a capacitor 19, the in the simple case is a large separating capacitor. This trap may at one point of the inductance 18, e.g. at a tapping point, but also at the connection point with the ondensatoren 16 and 17 or by means of a secondary winding, via the line 20 a signal can be taken, which as a result of the resonance occurring its own Provides sound signal at 33.4 MHz with increased amplitude.

At the same time, the image signal IF oscillations also occur with a Amplitude, which is in particular due to the voltage division ratio over the capacitor 16 and 17 to the pick-up point at the inductance 18a, 18b for the Line 20 results.

The transfer curve 21 to the line 20 is on the right below the Klen-ne 6 reproduced. It is shown in the attenuation level below one of the lines 22 corresponding reference level. Here are the aforementioned damping poles for the neighboring picture carrier of 31.9 MHz and for the neighboring sound carrier of 40.4 and 41.4 respectively MHz and the transmission maxima in the vicinity of the sound carrier of 33.4 MHz and the Image carrier of 38.9 MHz specified. By a dimensioning described below the partial inductances 18a and 18b and the capacitor 19 is another Attenuation pole introduced at around 36.1 MHz. The character is shown for line 20 a band filter.

The vibrations received from line 20 become one, preferably Circuit arrangement 25 implemented using integrated technology at a terminal 26 which is connected to the input of an optionally multistage, controllable amplifier 27 connected is.

The output signals of the amplifier 27 are used to obtain a Reference oscillation for the demodulation via a further amplifier 28 on the IF picture carrier oscillation of 38.9 MHz matched filter circuit 29 and then one Limiter amplifier 30 is supplied. The filter 29 can with a single circle a quality of 50 to 80 can be formed.

Through the filter 29, the picture carrier IF oscillation is 38.9 MHz with some of the neighboring vibrations transmitted as double sideband signals filtered out; there is also a phase shift by 900.

The vibrations filtered out in this way are severely limited in stage 30 such that the amplitude modulation caused by the sidebands is largely is eliminated and at the output of the stage a reference signal corresponding to the picture carrier IF is available, which is fed to a single sideband mixer 33.

The mixer 33 also receives the image signal IF oscillations The output signal of the amplifier 27 contained in the range of 33.4 MHz is supplied. In stage 33, which can be formed by a phase discriminator, takes place then a single sideband demodulation of the audio signal oscillations compared to the am Output of stage 30 obtained reference signal, so that at the output of stage 33 the sound signal difference frequency oscillations corresponding to the frequency difference between the video carrier and the sound carrier (Intercarrier signal) occur and via an amplifier 34 of the output terminal 35 are forwarded. The through the filter 29 conducted vibrations are restricted to the area around the image carrier; they shouldn't have a Nyquist flank have and are further by the limiter 30 of amplitude fluctuations and thus freed from the side ligaments. The 900 phase shift will continue a demodulation of the double sideband components in the mixer 33 is practical in this way prevents the audio signal difference frequency from predominantly occurring at the output. This is transmitted from terminal 35 in a known manner to a range around 5.5 MHz Band filter and then fed to the tone frequency demodulator.

Since in the manner described a demodulation of the picture carrier nearby double sideband components are avoided, the sync pulses will not be affected either corresponding signal component obtained in stage 33, which is used for control purposes could be.

According to a further development of the invention, there is therefore a further mixing stage 41 is provided, which is supplied with the output signal of stage 27 at both inputs becomes such that a squaring takes place. This makes the sync pulses stronger and signals of lower amplitude (e.g. the video signals) are more strongly suppressed. Compared to a reference signal, preferably also in stage 41, a Control signal is generated that shows the deviations from the setpoint, e.g. the peak value in the Line sync pulse interval. This control signal becomes a power generator stage 42 is supplied, the output current of which is fed to a capacitor 43, for example via a terminal 44 is arranged outside the integrated circuit 25, is supplied. This gets one an integrating control in such a way that the voltage across the capacitor 43 as long as is increased or decreased until the control error has become zero. The regulation takes place from the output of stage 42 and thus from capacitor 43 to the control amplifier 27

In the further stages connected to stage 35, e.g.

a limiter for the filtered-out tone difference frequency oscillations, non-linearities occur; the resulting harmonics or mixed products can produce oscillations in the range of 5.5 MHz, which are reflected in the audio signals as distortions. To additionally dampen such vibration components, can according to the embodiment, the inductance 18b of 0.62 / uH and the capacitance 19 of 33 pF as a series resonance circuit at 36.1 MHz, i.e. one from the carrier 38.9 MHz to be tuned by about 2.8 MHz deviating frequency, so that a corresponding Damping pole occurs in curve 21.

The transmitted through the filter 29 is transmitted to the Begre..zorvxsrstarkker 30 Signal supplied that also includes the double sideband components of the image signal carrier which extend up to about 1 MHz; in this area are in particular the direct current component of the picture content and the sync pulses. The input signal of stage 30 thus covers a considerable range of amplitudes. For a flawless The quality of the audio signal ultimately obtained depends on the output signal of the stage 30 is at least almost independent of the input amplitude and also otherwise works linearly so that the formation of disruptive harmonics is avoided. The stage 30 should also work in a frequency-linear manner and that which arises during the limitation Process harmonics of the video carrier well so that the limited signal obtained is as precisely rectangular as possible and as a stable reference oscillation for the mixer stage 33 can serve.

Fig. 2 shows a suitable integrable circuit that is symmetrical is designed so that the signals from the input to the output alternating current processed in push-pull.

The Ceg-clock input signal from the filter is applied to terminals 51 and 52 29 two emitter-follower transistors 53 and 54 with emitter resistors 55 and 56 of 1.5 kOhms, whose emitters are connected to the bases of transistors 57 and 58 are. These together form a differential amplifier by having their emitter above a resistor 59 of about 300 ears, possibly with parallel capacities 60, are connected and via St-mqeilentrasistoren 61 and 62 with emitter resistors 63 and 64 of 33Q Ohms can be controlled. The base voltages for the current cuelient transistors 61 and 62 are supplied from the base of a transistor 65, which is connected through a series resistor 66 of 10 kohm a current from the supply source + U of 12 V is supplied so that at the base-emitter path a corresponding voltage drop UBE and at the opposite Earth and thus the other pole of the supply source U connected resistor 67 of 330 ohms a corresponding voltage drop occurs. By means of a transistor 68, whose collector is connected to the supply voltage + U and whose base and emitter are connected to the collector or the base of the transistor 65, the required Current supply for the connected bases of the transistors 61, 62 and 65 ensured.

The collectors of transistors 57 and 58 are connected to the emitters of the TransisForen 71 and 72, respectively, are connected, initially the one from the dotted line 73 enclosed switching elements can be disregarded. The bases of the transistors 71 and 72 are connected and applied to the tap of a voltage divider, which is parallel to the supply source U and from the resistors 74 of 5.5 kOhm, 75 of 1.9 kOhm and 76 of 3.9 kOhms.

By d- connecting the bases of transistors 71 and 72 to the voltage divider these are practically placed at a fixed potential in such a way that the emitter of transistors 71 and 72 and the collectors of the transistors connected to them 57 and 58 carry practically no alternating voltage.

The transistors 57 and 58 are therefore controlled exclusively at base and emitter; this ensures a maximum linear dynamic range; the influence of the collector-base capacitance is eliminated.

The collectors of transistors 71 and 72 are individual Working resistors 77 and 78 of 220 ohms and a common resistor 79 of 1 kOhm connected to the supply source + U. The collector voltages of the transistors 71 and 72 control the bases of the emitter followers 81 and 82, their collectors at + U and their emitters are connected to earth via resistors 83 and 84 of 2.7 kOhm are; the output signals appear at terminals 85 and 86 and then become the Mixing stage 33 shown in FIG. 1 is supplied.

The differential amplifier with transistors 57 and 58 is set so that that saturation is reached even with low input voltages. Here can the indicated capacitor 60 also has a certain influence on the phase position can be achieved in such a way that together with the phase rotation possibly already effected in the filter 29 a total phase rotation of approximately 900 for the reference vibration of the milk level 33 is ensured.

In order to improve the effect of the amplifying limiter 30, can the circuit indicated within the dotted line 73 can be added. These consists of transistors 91 and 92 in series with transistors 71 and 72 are switched on and their bases also from a tap of the voltage divider, namely between the resistors 75 and 76, controlled and thus at a practically constant Potential to be maintained. The transistors 91 and 92 thus operate like the transistors 71 and 72 as transistor amplifiers in a basic basic circuit; on the one hand they cause a decoupling between input and output and on the other hand show a linear Behavior up to very high frequencies, which the fundamental wave of the IF picture carrier of Significantly exceed 39.8 MHz. In addition, a differential amplifier is still off the transistors 93 and 94 turned on, the connected emitter of which via another connected to the transistor 65 current source transistor 95 with emitter resistor 96 can be controlled by 160 ohms. As a result, the transistors 93 and 94 in the middle position the same currents as transistors 61 and 62; their control takes place as the difference between the current-dependent components of the base-emitter voltages of transistors 91 and 92, and the collector currents thus obtained are in a cross connection is added to the collector currents of transistors 93 and 91.

The circuit cell within the dotted line 73 thus effects a doubling of the output current with otherwise the same modulation and Frequency behavior.

As a result of the voltage divider 74, 75, 76 are the bases of the transistors in the basic basic circuit (71, 72, 91, 92) only via certain internal resistances to ground tied together. If an even lower resistance connection appears necessary, you can in a simple way emitter follower between the voltage divider taps and the Bases of the transistors concerned are turned on.

Claims (17)

Claims: 1. Circuit arrangement for obtaining the audio signals from a television signal transmitted on a high-frequency carrier, in which after a first mixture for obtaining the IF oscillations in a filter on the one hand the intermediate-frequency image signal band is separated and on the other hand a signal area, which is made up of the intermediate frequency sound signals and signals in the vicinity of the intermediate frequency Composite image carrier, removed and therefrom by a second mixture the audio signals are obtained in the difference frequency position, characterized in that the for the second mixture (step 33) required composite signal oscillations are decoupled from the image IF filter (1 to 19) by means of an IF sound carrier trap (16 to 19) behind at least one damping pole (parts 11 and 12) for one adjacent carrier of the upper and lower adjacent channel is arranged and in the also vibrations of the image carrier IF and, if necessary, at least to a part, vibrations of the neighboring, transmitted as a double sideband signal Modulation frequencies occur with an amplitude sufficient for mixing (Curve 21). 2. Circuit arrangement according to claim 1, characterized in that in the composite signal oscillations, the amplitudes of the sound carrier IF oscillations and the image carrier IF oscillations approximately in the ratio 1: 3 to 3: 1, preferably stand about 1: 1. 3. Circuit arrangement according to claim 1 or 2, characterized in that that the decoupling of the composite signal oscillations in a sound carrier trap (16 to 19) takes place, in which the image carrier IF oscillations a maximum approximately in the Close to the image carrier. 4. Circuit arrangement according to claim 3, characterized in that a Edge of the transmission curve leading to a maximum through the neighboring sound carrier trap (12) or the neighboring image carrier trap (11) is conditional. 5. Circuit arrangement according to one of the preceding claims, characterized characterized in that the composite signal oscillations of a sound carrier trap which is arranged at the output end of the image IF filter. 6. Circuit arrangement according to one of the preceding claims, characterized characterized in that the sound carrier trap (16 to 19), which the composite signal oscillations are taken as a damping pole for one of a subharmonics of the differential carrier frequency corresponding IF oscillation is formed. 7. Circuit arrangement according to claim 6, characterized in that the sound carrier trap (16 to 19) for the extracted composite vibrations a damping pole corresponding to half or a third of the tone difference frequency having. 8. Circuit arrangement according to one of the preceding claims, characterized characterized in that the composite signal oscillations via a on the picture carrier IF matched filter (29) and a limiter amplifier (30) of the second mixer stage (33) are supplied as reference vibrations. 9. Circuit arrangement according to claim 8, characterized in that the second mixer stage (33) the composite signal oscillations at the signal input are supplied and that the reference vibrations are supplied with a phase position which are around 9n0 compared to the picture carrier IF oscillations at the signal input is rotated. 10. Circuit arrangement according to claim 9, characterized in that the 90 ° phase shift at least partially in an integrated amplifier and / or limiter circuit (30) takes place. 11. Circuit arrangement according to claim 9 or 10, characterized in that that the 90 ° phase shift takes place at least partially in the mixing stage (33). 12. Circuit arrangement in particular according to one of the preceding Claims, characterized in that the composite signal oscillations on the one hand the signal input of a single sideband demodulator (33), in particular a phase discriminator, and on the other hand via a on the image carrier matched filter (29) of a limiter stage (30), which the reference oscillations for the single-sided band demodulator (33). 13. Circuit arrangement according to claim 9 to 12, characterized in that that the 90 ° phase shift is at least in part by means of, e.g., the limiter amplifier (30) upstream, filter (29) takes place. 14. Circuit arrangement according to one of the preceding claims 8 to 13, characterized in that the limiter (30) by an amplifier, preferably a differential amplifier (57, 58) is formed, the output of which has at least one another transistor (71, 72) controls in the basic basic circuit. 15. Circuit arrangement according to claim 14, characterized in that that between the differential amplifier (57, 58) and the or the further transistor (s) (71, 72) an additional transistor (91 or 92) is switched on in the basic basic circuit and that each collector of the differential amplifier (57, 58) with the base input of another differential amplifier (93,94) is connected, the collector outputs of which cross with the collectors of the further transistors (91, 92) are connected in a basic basic circuit. 16. Circuit arrangement according to one of the preceding claims, characterized characterized in that the composite signal oscillations are squared (stage 42) and from this an amplitude control signal is formed in relation to a reference value will. 17. Circuit arrangement according to claim 16, characterized in that that the amplitude control signal is fed as a current (stage 42) to a capacitor (43) whose voltage causes the gain control (stage 27).